BACKGROUND OF THE INVENTION1. Field of the Invention
This invention describes a modular food dehydrator adapted for use with a conventional room fan.
2. Description of Related Art
The preservation of foodstuffs by dehydration is well known in the art. The simplest and oldest forms of food dehydration involves stakes, linesm, platforms and the like, where food is exposed to the sun and the air. In some cases, heat is applied to speed the drying process, such as by staking food alongside an open fire.
Many mechanical devices have been developed in modern times, for both commercial and large scale dehydration, and also for home use. Most such devices provide a shelf with openings to allow for air circulation around the food, and means for moving air through and around food that has been placed on the shelf. In many home dehydrator devices, the dehydrator incorporates a motor driven fan to push air through the openings and generally circulate air about the food in the dehydrator. A heater is also typically provided for heating the air before it is circulated by the fan. Such a device is disclosed in U.S. Pat. No. 5,458,050.
U.S. Pat. No. 4,536,643, teaches a cylindrical food dehydrator that includes a base member, a plurality of stackable trays, and a top. The base member has a first chamber adapted to receive a heater element for convection air distribution and a second chamber adapted for a heating element for forced air distribution. The device is thereby convertible between a convection heating made and a forced air heating made.
U.S. Pat. No. 5,878,508, describes a modular food dehydrator utilizing a combination heater and blower assembly that is located on a top surface of a dehydrator modular food tray. The heater and blower assembly includes a motor driven fan, a heating element and an air distribution portion for directing heated air across the support surfaces. This dehydrator modular food tray also includes outlet vents on an outer perimeter surface for exhausting the heated air. In such a device, the air is both warmest and driest at the first tray, and becomes progressively cooler and more humid as it reaches lower trays. Therefore, the food on the trays closest to the hot air source get very dry, while that furthest from the source dries more slowly. U.S. Pat. No. 6,085,442, discloses a similar modular food dehydrator utilizing a heater and blower assembly located on a top surface of a dehydrator.
These prior devices have numerous electrical and moving parts, and are often complicated to use, and to achieve even drying of the food. Locating the heating element and blower motor in the base of a unit also creates cleaning problems. Bases are typically not dishwasher safe. Additionally, the base can become contaminated with drippings that fall through the perforations in the trays, creating a potential health hazard. If meat products are dried, the grease drippings may create a fire.
A blower component is also the most likely component to fail, and as the greatest cost component, it is often the case that it is easier to replace an entire dehydrator unit than attempt to repair. This is particularly so with the many food dehydrators that produce heated air by use of a heating element. For this reason, present dehydrators are expensive and prone to failure, or costly repair and/or replacement.
None of the prior approaches have been able to provide a simple and powerful dehydrator that can be adapted for use with a simple house fan.
SUMMARY OF THE INVENTIONThis invention provides a food dehydrator apparatus comprising a plurality of modular food trays, each modular food tray comprising a generally horizontal drying rack having an upper and lower surface, openings providing for air passage extending generally vertically through the trays, and a wall located at the periphery of the support structure. The wall extends generally vertically at the periphery, and has a top and bottom edge, and an inner and outer wall surface. The apparatus also has a plurality of legs extending from the lower surface of the drying rackand beyond the lower edge of the wall, where the modular food trays are stackable, whereby when a first modular food tray is adjacent a second modular food tray, the top edged of the wall of the first modular food tray and the bottom edge of the wall of the second modular food tray form a close fit preventing air passage therebetween, and when the first modular food tray is set on a substantially flat support surface with the legs set on the support surface, a gap is formed between the wall bottom edge and the support surface.
In one preferred embodiment, the apparatus has a drying rackthat comprises intersecting support elements forming open and closed spaces therein. In a further preferred embodiment, the intersecting support elements comprise two sets of elongated and parallel structures intersecting at right angles.
In a still further preferred embodiment, the support elements have a diamond configuration in cross section. Alternatively, the support elements may comprise intermittent raised portions along their upper surface.
In a different embodiment, the intersecting support elements comprise respective radial and circular sets of structures, preferably where the radial support elements are biased to direct air flow circularly through an assembled apparatus.
The top wall edge is preferably sized to accomodate the outer dimensions of a standard household fan.
In another preferred embodiment, a central support leg extends from the lower surface of the support structure.
The invention also contemplates a food dehydrator kit comprising a fan and a plurality of the described modular food trays. In a preferred such embodiment, the fan is a household fan. Preferred household fans come in dimensions of twenty inches square and ten inches square.
The invention further provides a method for dehydrating food comprising assembling a food dehydrator apparatus and either before, during or after the assembly, placing food onto the upper surface of at least one modular food tray support structure, and circulating room temperature air through the apparatus be actuating the fan.
These and other features and advantages of this invention are described in, or are apparent from, the following detailed description of various exemplary embodiments of the apparatus and methods according to this invention.
BRIEF DESCRIPTION OF THE DRAWINGSFIG. 1 shows a perspective drawing showing the modular tray.
FIG. 2 is a different perspective drawing showing additional features of the modular tray.
FIG. 3 is a side view of the modular tray ofFIG. 1.
FIG. 4 depicts a plan view of the tray ofFIG. 1.
FIG. 5 depicts a plan view of an alternative tray, with a radial support configuration.
FIG. 6 is view of a tray assembly showing stacked modular trays and a fan.
FIG. 7 is a cut away view showing the modular tray cut along the line in9-9 inFIG. 4.
FIG. 8 is a cut away view showing the modular tray cut along the line in8-8 inFIG. 5.
FIG. 9 is a cut away view showing an alternative modular tray as cut along the line in9-9 inFIG. 4.
DETAILED DESCRIPTION OF THE INVENTIONThe apparatus, kit and methods of the present invention provide a food simple and effective modular food dehydrator system, using an apparatus that can be easily assembled and disassembled of modular tray units and a readily available household fan. The modular units of the dehydrator apparatus have no moving parts, electrical systems or machinery that can be a source of failure.
Looking toFIG. 1, which shows a perspective view of amodular food tray10 of the apparatus from a lower positions, the apparatus includes a plurality ofmodular food trays10, eachsuch tray10 comprising a generallyhorizontal drying rack12 having anupper surface14 and lower surface16 (FIG. 2). The tray further hasopenings18 for providing air passage generally vertically through the trays.
Each tray also has awall20 located at the periphery of thetray10. Thewall20 extends generally vertically at the tray periphery, and has atop edge22 andbottom edge24, as well as aninner wall surface26 andouter wall surface28.
The trays also come with a plurality oflegs30 extending from thelower surface16 of thedrying rack12 and beyond thewall bottom edge24.
When two trays are stacked, the first or lower tray is rested against a flat support surface, such as a finished floor, and a second tray is nested onto the first tray. As best seen inFIG. 2, which provides a view of the tray ofFIG. 1 from a top perspective, theupper surface14 of thedrying rack12 can be provided withelevations32 for nesting with thelegs30 of anadjacent tray10 when two ormore trays10 are stacked together.
As seen inFIG. 3, where thetray10 is large, it may be desirable to include acentral support leg34, which extends from thelower surface16 of thedrying rack12. As seen inFIG. 1, acentral elevation36 along theupper surface14 of thedrying rack12 can be provided for supporting the central support leg of an adjacenent nested tray.
For purposes of further alignment, guides38 can ge provided in theupper surface14 of the drying rack12 (FIG. 1), andslots40 in thelower surface16 of the drying rack12 (FIG. 2). These guides38 andslots40 provide good alignment of thewalls20 of nestedtrays10.
In reference toFIGS. 4 and 5, thedrying rack12 hasopen spaces18 to allow circulation of air around food placed on theupper surface14 of thedrying rack12.
Theopen spaces18 can be manufactured through a number of mechanisms, all well known to the art. InFIG. 4, the open spaces are formed fromsupport elements42. In thetray10 of the embodiment shown inFIG. 4, two perpendicular sets of elongated andparallel structures44 and46 provide thesupport elements42, which form a square grid-like pattern at intersecting right angles. Thesupport elements42 form the solid, closed surface that makes contact with and supports food being placed on thedrying rack12, while also defining theopen spaces18.
In the embodiment shown inFIG. 5, the intersectingsupport elements42 comprise respective radial48 and circular50 sets of structures.
Thetrays10 are preferably dishwasher safe and immersible in water. They are most easily produced by injection molding, employing a plastic resin, such as polypropylene, polyethylene and polyester. Thetrays10 may also be produced from recycled plastics, and the like. All such injection molding methods, materials, and apparatuses are well known to the art.
The present invention is also directed to a method of operating the food dehydrator apparatus. As seen in reference toFIG. 6, the method for dehydrating food using the apparatus comprises assembling afood dehydrator apparatus100 from at least onfood tray10 and ahousehold fan110. In the drawing there are four nestedtrays10, but in practice as many as12 or20 or more trays could be nested, depending on the strength of thefan110 to push air throughapparatus100. The fan is nested and located within the top most tray. As also seen in reference toFIG. 6, theguides38 may also be produced in thetray10 to assist in positioning thefan110 over theopenings18 in thedrying rack12.
Thetop wall edge22 is sized to allow easy insertion by being larger in circumference than the outer dimensions of a standard household fan. Theopen spaces18, however, are best covered by thefan110 outer dimensions, in order to direct all of the circulating air into the interior of theapparatus100.
When theapparatus100 is assembled, thetop edge22 of thewall20 of the first modular food tray and thebottom edge24 of the wall of the second modular food tray form a close fit. This can be a tight friction fit. The tighter the tolerance, the better theapparatus100 is at preventing air passage therebetween. As noted above, theguides38 andslots40 provide good alignment of the thetop edge22 of thewall20 of a first modular food tray with thebottom edge24 of the wall of a second modular food tray, when the first and second are nested.
When a firstmodular food tray10 is set on a substantially flat support surface (not shown) with thelegs30 set on the support surface, a gap is formed between thewall bottom edge24 and the support surface, the gap being set by the length of thelegs30. The gap essentially forms outlet vents at the base of the lower most unit, for venting the air circulated at the topmost tray by thefan110.
Thefan110 can be a household fan, sometimes referred to as a box fan. Household fans come in various dimensions, but the most popular are fans of twenty inches square and ten inches square in size. Such household fans are well known to the consuming public, and are generally very inexpensive. Thus, in the event that there is a breakdown in thefan110, which is the only and one aspect of thedehydrator apparatus100 that has moveable or electric parts, it is a simple matter to replace. For these reasons, thetrays10 are preferably produced in sizes of ten inches and twenty inches square, or slightly larger as necessary to accommodate the fan.
As shown inFIG. 6, the modular food trays can be produced such that food will be secured between close upper and lower surfaces of respective drying racks12, and themodular food trays10 andfan110 assembled or stacked horizontally in an apparatus that vents the air into the room rather than against a floor or other support surface.
Either before, during or after assembling theapparatus100, food (not shown) is placed onto theupper surface12 of at least onetray10. The fan is then actuated, and room temperature air is circulated through the apparatus be the action of the fan.
While it is contemplated that thetrays10 can be provided in packages to consumers, theapparatus100 may be provided as a food dehydrator kit comprising afan110 and a plurality of the describedmodular food trays10.
Food suitable for dehydration is almost limitless. Commonly dehydrated foods include a number of fruits, such as apple, pear, pineapple, stone fruits, tropical fruits and various berries. Almost any vegetable can be dried. Finally, many varieties of meats, including game meets, are commonly dehydrated for storage and preservation. Preferably the fruit, vegetable, or meat be prepared to present a cut surface to the circulating air.
Since the amount of surface exposed to the air is a limitation on the dehydration process, thesupport elements42 should be a small in diameter as is practicle. Looking toFIG. 7 thesupport elements42 can be produced with a diamond configuration in cross section (see cutaway). In this embodiment, the diamond shape limits the amount of thesupport element42 in actual contact with the food.
FIG. 8 and the cutaway show thesupport structure42 of the embodiment shown inFIG. 5, it is seen how the support element, particularly theradial structure48, can be used to further direct the air flow through the apparatus. In the cutaway it is seen that theradial structures48 are biased to direct air flow circularly through an assembled apparatus, by each being non-vertical to some degree. A relatively small bias in eachradial structure48, over eachtray10 stacked in a multi-tray apparatus can create a significant redirection of air flow from thefan110 through theapparatus100.
FIG. 9 discloses a further embodiment of thesupport structure42 to reduce contact with the food surface. In this embodiment, thesupport structures42 have intermittent raisedportions120 along their upper surface. These raisedportions120 create small points of contact to elevate the dehydrating food portions above theupper surface14 of thedrying rack12, thereby increasing the surface area of food directly in contact with the circulating air.
The dehydrating performance of the food dehydrator has been assessed and shown to rapidly and efficiently produce dehydrated fruits, vegetables and meats.
While this invention has been described in conjunction with the specific embodiments outlined above, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the preferred embodiments of the invention, as set forth above, are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of this invention.